From Fluorescence‐Transfer‐Lightening‐Printing‐Assisted Conductive Adhesive Nanocomposite Hydrogels toward Wearable Interactive Optical Information‐Electronic Strain Sensors

Su, Gongmeiyue; Wang, Ni; Liu, Yangkun; Zhang, Ruoyao; Li, Zhao; Deng, Yulin; Tang, Ben Zhong

doi:10.1002/adma.202400085

Advanced Materials

2024

DOI: 10.1002/adma.202400085

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From Fluorescence‐Transfer‐Lightening‐Printing‐Assisted Conductive Adhesive Nanocomposite Hydrogels toward Wearable Interactive Optical Information‐Electronic Strain Sensors

Gongmeiyue Su,

Ni Wang,

Yangkun Liu

et al.

Abstract: The interactive flexible device, which monitors the human motion in optical and electrical synergistic modes, has attracted growing attention recently. The incorporation of information attribute within the optical signal is deemed advantageous for improving the interactive efficiency. Therefore, the development of wearable optical information‐electronic strain sensors holds substantial promise, but integrating and synergizing various functions and realizing strain‐mediated information transformation keep chall… Show more

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Cited by 8 publications

References 77 publications

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Hydrophobic and Adhesive Elastomer Encapsulation for Anti‐Drying, Non‐Swelling, and Adhesive Hydrogels

Yuan,

Zhu,

Huang

et al. 2024

Adv Funct Materials

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Traditional hydrogels often face issues like dehydration, excessive swelling, and poor adhesion, limiting their practical applications. This study presents a facile and universal method to create elastomer‐encapsulated hydrogels with improved water retention, non‐swelling, and enhanced adhesion. n‐Butyl acrylate (BA) and 2,2,3,4,4,4‐hexafluorobutyl methacrylate (HFBMA) are utilized as the “soft” and “hard” monomers, respectively, to in situ construct the elastomer coatings on the hydrogel surface through surface‐confined copolymerization. The resulting transparent, hydrophobic, and adhesive elastomer coating is tightly bound to the hydrogel surface, conferring upon it a robust defense against dehydration and swelling in various media, and strong adhesion to diverse substrates in both aerial and submerged conditions. Furthermore, this encapsulation strategy also augments the mechanical attributes of the bulk hydrogel, including its tensile properties and puncture resistance, and is applicable to a wide array of hydrogel types and configurations. Additionally, the in situ encapsulation method applied to conductive hydrogels results in flexible sensors with high sensitivity, reversible resistance change, exceptional sensing stability, and significantly enhanced durability in both air and underwater environments. These properties suggest potential applications in harsh environments, such as underwater acoustic detection and sonar scanning camouflage for submarines.

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Hydrophobic and Adhesive Elastomer Encapsulation for Anti‐Drying, Non‐Swelling, and Adhesive Hydrogels

Yuan,

Zhu,

Huang

et al. 2024

Adv Funct Materials

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Rational Designed Polymeric Rigid Cages for Trapping Bulky Vegetable Oils toward Versatile Bio‐Based Adhesives

Zhang,

et al. 2024

Adv Funct Materials

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Polymer gels stand out as emerging and promising materials in adhesives. However, flexible network and network–solvent mismatch affect their strengths and stabilities. Regulating the network architectures of polymer gels via molecular design is a promising strategy to overcome these drawbacks. Herein, a novel polymeric rigid cage (PRC) network structure design is proposed for capturing bulky vegetable oils via mechanically interlocking supramolecular interactions or steric hindrance effect to fabricate universal polymer gels‐based adhesives. By rationally designing and refining the architectures, the rigid cage prepared by 4,4′‐diphenylmethane diisocyanate (MDI) and N,N,N″,N″‐tetra(2‐hydroxypropyl) ethylenediamine (EDTP) possesses optimal encapsulation effect for epoxidized linseed oil (ELO). The resulting RCE‐50 gel exhibited robust mechanical properties (≈65 MPa) and excellent stability (high temperatures, high pressures, solvents immersion). Owing to high strength and stability of the polyurethane network, adhesion effect of high‐density amino ester groups, as well as the hydrophobic and toughening effects of ELO, the RCE‐50 gel can be used as a versatile adhesive with high adhesive strength under different conditions. This study proposes a new approach for innovating the properties of polymer gels, provides a novel idea for designing porous polymer materials, and offers fresh insights for developing versatile bio‐based adhesives.

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Quasi‐1D Conductive Network Composites for Ultra‐Sensitive Strain Sensing

Gao,

Xu,

et al. 2024

Advanced Science

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Highly performance flexible strain sensor is a crucial component for wearable devices, human‐machine interfaces, and e‐skins. However, the sensitivity of the strain sensor is highly limited by the strain range for large destruction of the conductive network. Here the quasi‐1D conductive network (QCN) is proposed for the design of an ultra‐sensitive strain sensor. The orientation of the conductive particles can effectively reduce the number of redundant percolative pathways in the conductive composites. The maximum sensitivity will reach the upper limit when the whole composite remains only “one” percolation pathway. Besides, the QCN structure can also confine the tunnel electron spread through the rigid inclusions which significantly enlarges the strain‐resistance effect along the tensile direction. The strain sensor exhibits state‐of‐art performance including large gauge factor (862227), fast response time (24 ms), good durability (cycled 1000 times), and multi‐mechanical sensing ability (compression, bending, shearing, air flow vibration, etc.). Finally, the QCN sensor can be exploited to realize the human‐machine interface (HMI) application of acoustic signal recognition (instrument calibration) and spectrum restoration (voice parsing).

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From Fluorescence‐Transfer‐Lightening‐Printing‐Assisted Conductive Adhesive Nanocomposite Hydrogels toward Wearable Interactive Optical Information‐Electronic Strain Sensors

Cited by 8 publications

References 77 publications

Hydrophobic and Adhesive Elastomer Encapsulation for Anti‐Drying, Non‐Swelling, and Adhesive Hydrogels

Hydrophobic and Adhesive Elastomer Encapsulation for Anti‐Drying, Non‐Swelling, and Adhesive Hydrogels

Rational Designed Polymeric Rigid Cages for Trapping Bulky Vegetable Oils toward Versatile Bio‐Based Adhesives

Quasi‐1D Conductive Network Composites for Ultra‐Sensitive Strain Sensing

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